Multiplier circuit for multiplication operation between binary and twos complement numbers

ABSTRACT

A multiplier circuit which multiplies together both natural and two&#39;s complement binary numbers, which it receives in the form of electric signals having predetermined logic values, that are applied to input terminals of logic gating circuits. The logic gating circuits provide partial products of the bits of the two binary numbers, and a combinatorial network provides the final sum of the partial products. The partial products that include at least one of the more significant bits of either of the operands are performed by logic gating circuits which can be enabled to complement the partial product. The multiplier circuit further includes additional logic gating circuits which supply the combinatorial network with additive constants with predetermined logic values.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims foreign priority from European Patent No. 94830581.8, filed Dec. 22, 1994.

TECHNICAL FIELD

This invention relates to multiplier circuits for accomplishing operations with binary numbers, and in particular, to a monolithically integratable multiplier circuit which can be used in integrated circuit microprocessors or microcontrollers.

BACKGROUND OF THE INVENTION

Among the circuits for carrying out arithmetical operations of multiplication, multipliers having a typical, iterative structure or architecture known as a “cellular array” have been found to be especially advantageous.

Assuming that two integers expressed in natural binary form with 4 parallel-supplied bits are to be multiplied together,

A=a₃*2³+a₂*2²+a₁*2+a₀

B=b₃*2³+b₂*2²+b₁*2+b₀

then the product is,

A*B=b₀(a₃*2³+a₂*2²+a₁*2+a₀)+2b₁(a₃*2³+a₂*2²+a₁*2+a₀)+4b₂(a₃*2³+a₂*2²+a₁*2+a₀)+8b₃(a₃*2³+a₂*2²+a₁*2+a₀)

Therefore, the product of A by B is obtained by adding together the partial products wherein the terms making up the following matrix appear:

a₃b₀ a₂b₀ a₁b₀ a₀b₀ a₃b₁ a₂b₁ a₁b₁ a₀b₁ a₃b₂ a₂b₂ a₁b₂ a₀b₂ a₃b₃ a₂b₃ a₁b₃ a₀b₃

There are several different types of algorithms whereby the sum of the partial products thus computed can be reckoned. Iterative array multipliers consist of a combinatorial network which performs this addition with a delay which is only dependent on the time required to go through the various logic circuits.

The computation of the matrix of partial products is accomplished using a combinatorial network of logic AND gating circuits whereby all the matrix bits are obtained simultaneously with just the delay of a simple logic product. If the size of the operands is of n bits, then n*n AND gates will be required.

There are several circuit architectures that can provide the sum of the individual logic products making up the partial product matrix. Of considerable import is Dadda's algorithm, described in an article entitled “Some Schemes for Parallel Multipliers”, Alta Frequenza, Vol. XXXIV, No. 5, May 1965, which yields the sum of the individual partial products by compressing the matrix columns, that is progressively reducing the number of the rows which make up the partial product matrix by adding together the bits in one column until two rows only are obtained whose sum, representing the result of the multiplication, is obtained using a fast adder. Thus, the multiplier is composed of three parts: the matrix structure of AND gates which is to compute the partial products, the circuit for compressing the columns, and the final adder.

For effecting the column compression portion of the procedure, parallel counters may be used, that is components which will count the number of bits equal to 1 present at their inputs; where two inputs only are provided, these would be so-called Half-Adders (“HA”), whereas with three inputs provided, these would be so-called Full Adders (“FA”). However, they may also be defined for any number of inputs greater than three.

Dadda uses both FAs and HAs in his multiplier, and shows that the best method (i.e., that requiring the smallest number of cells) consists of compressing the columns such that the number of rows which make up the partial product matrix decreases in accordance with the following recursive formula:

d(0)=2

d(k+1)=3/2d(k)

where, d(i) is the number of rows in the i-th stage, and k is the number of stages required for the reduction.

Thus, the following series is generated:

k 0 1 2 3 4  5  6  7  8  9 d(k) 2 3 4 6 9 13 19 28 42 63

For example, in the 8×8 case, the initial number (8) of the rows must be reduced to 6, 4, 3, and ultimately 2; accordingly, 4 stages are required.

The algorithm provides for the use of FAs and HAs arranged in a structure which ensures that no more than d(k) rows exist in the k-th stage.

Also described in the article is Wallace's block diagram, and reflections are offered on the parallel adders used in binary number multipliers.

In another, more recently published article by L. Dadda, entitled “On Parallel Digital Multiplier”, Alta Frequenza, Vol. XLV, No. 10, October 1976, the parallel implementation of the adders is dealt with, using “fast” storage elements to provide high-speed digital multipliers.

The technique employed for multiplying natural binary numbers may also be used for relative numbers, expressed in binary form, by representing the negative value numbers in the two's complement binary form. The necessary add operation is carried out by two's complementing the negative terms. This allows the complexity of the arithmetic circuits of a processor to be greatly reduced and, accordingly, the speed of operation increased.

Known are natural number multipliers, two's complement binary number multipliers, and multipliers which either enable two natural binary numbers or two's complement binary numbers to be multiplied together.

However, there is an unmet need in the art for a multiplier circuit for accomplishing multiplication operations with two binary operands, each operand either in the natural or two's complement form, as desired.

SUMMARY OF THE INVENTION

The present invention provides a multiplier circuit that performs multiplication operations with two binary operands, either of which may be in natural or twos complement form. This is achieved without prejudice for the high-speed and design simplicity features of conventional multiplier circuits, in particular Dadda's circuits.

A multiplier circuit multiplies together both natural and two's complement binary numbers, which it receives in the form of electric signals having predetermined logic values, that are applied to input terminals of logic gating circuits. The logic gating circuits provide partial products of the bits of the two binary factors, and a combinatorial network provides the final sum of such partial products. The partial multiplications that include at least one of the more significant bits of the operands are performed by logic gating circuits which can be enabled to also carry out a two's complement partial multiplication. The multiplier circuit further includes additional logic gating circuits which supply the combinatorial network with additive constants with predetermined logic values unrelated to the factors.

BRIEF DESCRIPTION OF THE DRAWINGS

The features and advantages of a multiplier circuit according to the invention will be apparent from the following description of an embodiment thereof, given by way of non-limitative example with reference to the accompanying drawings.

FIGS. 1, 2 and 3 show possible circuit arrangements implementing the logic gating circuits which are to provide the partial products of the binary factors with two's complement function;

FIG. 4 shows a first additional logic gating current according to the invention;

FIG. 5 shows a second additional logic gating current according to the invention;

FIG. 6 shows a third additional logic gating circuit according to the invention;

FIG. 7 shows a first example of a combinatorial network for combining partial products according to the present invention;

FIG. 8 shows a second example of a combinatorial network for combining partial products according to the present invention; and

FIG. 9 shows a block diagram for a vectorial calculus unit incorporating a multiplier circuit according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

Many of the known multiplier circuits use factor re-coding techniques, such as Booth's algorithm, to provide high-performance capabilities.

Such re-coding techniques allow the multiplication operation to be greatly simplified in that they allow the number of the partial products entering the computation to be reduced preliminarily, thereby reducing the time required for the multiplication, or the physical size of the multiplier circuit.

In accordance with the invention, the multiplier circuit has instead an iterative structure of a standard type, which is matched to the four product types involved by appropriate logic circuits effective to serve functions of partial product complementing and of adding additive constants which are independent of the operands, using the so-called method of the additive constants for computing the product.

As previously stated, both factors may be natural numbers, two's complement numbers, or one may be a two's complement and the other a natural number.

It can at all events be shown that all the cases of the possible products for current devices, such as 8×16 bits or 16×16 bits, can be encompassed by one or more multiplications of 8×8 bits belonging to one of the following four types. The factors A and B are designated as follows:

A=a₇a₆a₅a₄a₃a₂a₁a₀

and

B=b₇b₆b₅b₄b₃b₂b₁b₀

a) 8×8 multiplication—where a₇ and b₇ have positive weight, and therefore, the partial products a₀b₀. . . a₇b₇ (designated X in the following charts) are added in the natural mode; the matrix of partial products has the following structure:

X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X

Thus, the product of natural A and natural B will be a natural number.

b) 8×8 multiplication—where b₇ has negative weight. In this case, those partial products which contain bit b₇ should be complemented, and a suitable constant should be added to the result of the multiplication (elements to be complemented are underlined):

X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X  100000001

Thus, the product of natural A and relative B will be a relative number.

c) 8×8 multiplication—where a₇ has negative and b₇ positive weight. Here, it is the partial products which contain a₇ that should be complemented. In view of the structure being symmetrical with the case b) above, the additive constant will be the same.

X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X  100000001

The product of relative A and natural B will, therefore, be a relative number.

d) 8×8 multiplication—where both a₇ and b₇ have negative weight. The partial products which contain a₇ and b₇ should be complemented except a₇b₇.

The additive constant will be the sum of the constants in the previous two cases b) and c).

X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X  100000001

Thus, the product of relative A and relative B will be a relative number.

The example of the partial product matrix resulting in the instance of 8×8 bits, to which can be reduced as mentioned even the more complex cases of 8×16 bits and 16×16 bits, is in no way limiting.

The same method can be used for cases of m×n bits, where m and n are any selected integers.

Those elements which belong to the main diagonal of the partial product matrix should, therefore, be complemented if a multiplication of the c) or d) type is to be performed, while those in the bottom row should be complemented in the instance of a b) or d) operation. The matrix of partial products should, moreover, be added bits representing the additive constant. In the b) and c) cases, the additive constant is given by the following sequence of bits:

1000000100000000

and in the d) case by:

1000001000000000.

In the a) situation, the constant would be zero.

These considerations can be accounted for by introducing three bits, P, Q and S, into the partial product matrix in accordance with a scheme as shown here below:

E₈ a₆b₀ a₅b₀ a₄b₀ a₃b₀ a₂b₀ a₁b₀ a₀b₀ E₉ a₆b₁ a₅b₁ a₄b₁ a₃ b₁ a₂b₁ a₁b₁ a₀b₁ E₁₀ a₆b₂ a₅b₂ a₄b₂ a₃ b₂ a₂b₂ a₁b₂ a₀b₂ E₁₁ a₆b₃ a₅b₃ a₄b₃ a₃ b₃ a₂b₃ a₁b₃ a₀b₃ E₁₂ a₆b₄ a₅b₄ a₄b₄ a₃ b₄ a₂b₄ a₁b₄ a₀b₄ E₁₃ a₆b₅ a₅b₅ a₄b₅ a₃ b₅ a₂b₅ a₁b₅ a₀b₅ E₁₄ a₆b₆ a₅b₆ a₄b₆ a₃ b₆ a₂b₆ a₁b₆ a₀b₆ E₇ E₆ E₅ E₄ E₃ E₂ E₁ E₀ P Q S

which represents the partial product matrix in its most general form, again for the preferred example with 8-bit numbers.

Shown in more detail in the two charts that follow is the value taken by the functions E₀, E₁, E₂, . . . , E₁₄, P, Q and S in each of the four cases, identified here by two bits X and Y.

X Y E0 E1 E2 E3 E4 E5 E6 E7 a 0 0 a₀b₇ a₁b₇ a₂b₇ a₃b₇ a₄b₇ a₅b₇ a₆b₇ a₇b₇ b 0 1 {overscore (a₀b₇)} {overscore (a₁b₇)} {overscore (a₂b₇)} {overscore (a₃b₇)} {overscore (a₄b₇)} {overscore (a₅b₇)} {overscore (a₆b₇)} {overscore (a₇b₇)} c 1 0 a₀b₇ a₁b₇ a₂b₇ a₃b₇ a₄b₇ a₅b₇ a₆b₇ {overscore (a₇b₇)} d 1 1 {overscore (a₀b₇)} {overscore (a₁b₇)} {overscore (a₂b₇)} {overscore (a₃b₇)} {overscore (a₄b₇)} {overscore (a₅b₇)} {overscore (a₆b₇)} a₇b₇

X Y E8 E9 E10 E11 E12 E13 E14 a 0 0 a₇b₀ a₇b₁ a₇b₂ a₇b₃ a₇b₄ a₇b₅ a₇b₆ b 0 1 a₇b₀ a₇b₁ a₇b₂ a₇b₃ a₇b₄ a₇b₅ a₇b₆ c 1 0 {overscore (a₇b₀)} {overscore (a₇b₁)} {overscore (a₇b₂)} {overscore (a₇b₃)} {overscore (a₇b₄)} {overscore (a₇b₅)} {overscore (a₇b₆)} d 1 1 {overscore (a₇b₀)} {overscore (a₇b₁)} {overscore (a₇b₂)} {overscore (a₇b₃)} {overscore (a₇b₄)} {overscore (a₇b₅)} {overscore (a₇b₆)}

These charts represent the truth table for the two's complement functions added to the partial product matrix, while the additive constant can be calculated as follows:

P=X+Y

Q=X·Y

S=X⊕Y

where the logic operations specified are of the OR, AND and EXOR types, respectively.

In a similar way to conventional multiplier circuits, the multiplier circuit of this invention includes a structure with logic gating circuits for receiving, in the form of electric signals having predetermined logic values, the two binary numbers which are to be multiplied together and for obtaining the partial products shown in the general matrix layout.

In the most general of cases, this structure includes m groups of n logic gating circuits, where m and n are the bits of the two binary numbers to be multiplied, which would usually have the same number of bits (m=n).

Such logic gating circuits have first and second input terminals for the electric signals and an output terminal which is connected to a combinatorial network for the final summing of the partial products.

Applied to the first input terminal of all the logic gating circuits in one group is one of the m electric signals which encode one of the two binary numbers.

The second input terminal of each logic gating circuit in one group instead receives one of the n electric signals which encode the other binary number, which signal would be a different one for each logic gating circuit in one group.

According to this invention, those logic gating circuits which receive electric signals corresponding to the most significant bits of the two binary numbers (at both, or at least one of, the first and second input terminals) and carry out the operations with two's complement function, as indicated in the matrix layout by the character E, also have at least a third input terminal and may even have a fourth input terminal.

These terminals receive, for all the logic gating circuits mentioned above, similar electric control signals having predetermined values, whereby each of the logic gating circuits can be enabled to also carry out a two's complement operation on the product of the signals applied to the first and second input terminals.

The logic gating circuits with two input terminals may be provided as standard logic AND circuits. However, the logic gating circuits with four input terminals may be implemented with differently if desired.

FIG. 1 shows an implementation of those logic gating circuits which provide the partial products with two's complement function, E₀, E₁, E₂, E₃, E₄, E₅ and E₆. The logic gating circuit 1 of FIG. 1 has first, second, and third input terminals. First, input terminal receives a bit of the first number A to be multiplied. The logic gating circuit 1 providing partial product E₀ receives bit a₀ at the first input terminal; the logic gating circuit 1 providing partial product E₁receives bit a₁ at the first terminal A, and so on for the bits of the first number to be multiplied. For example, in an 8-bit number, the logic circuit 1 providing partial product E₇ receives bit a₇ at the first input terminal. On the other hand, the logic circuit 1 of FIG. 1 is coupled to receive bit b₇ at the second input terminal regardless of the partial product provided. The logic circuit of FIG. 1 has a third input terminal coupled to receive bit Y.

The first input terminal is coupled to a first input terminal of NOR gate 2. The first input terminal is also coupled to an input terminal of a first inverter 4. The second input terminal is coupled to a first input terminal of a second NOR gate 6 and is also coupled to an input terminal of a second inverter 8. The third input terminal is coupled to an input terminal of a third inverter 10 and is also coupled to a first input terminal of a third NOR gate 12.

The output terminal of third inverter 10 is coupled to a second input terminal of first NOR gate 2 and to a second input terminal of second NOR gate 6. The output terminal of second inverter 8 is coupled to a second input terminal of third NOR gate 12, and the output terminal of first inverter 4 is coupled to a third input terminal of third NOR gate 12. The output terminals of first NOR gate 2, second NOR gate 6, and third NOR gate 12 are coupled to first, second and third input terminals of fourth NOR gate 14, respectively. The output terminal of fourth NOR gate 14 provides the partial product. When bit Y is high, i.e., a logic 1, the logic circuit 1 of FIG. 1 is enabled to perform a two's complement logic multiplication operation.

FIG. 2 shows an implementation of the logic gating circuit which provides E₇. The logic circuit 15 of FIG. 2 has a first input terminal coupled to receive bit a₇, a second input terminal coupled to receive bit b₇, a third input terminal coupled to receive bit X, and a fourth input terminal coupled to receive bit Y. The first input terminal is coupled to a first input terminal of NAND gate 16, and the second input terminal is coupled to a second input terminal of NAND gate 16. The third input terminal is coupled to a first input terminal of exclusive NOR gate 18, and the fourth input terminal is coupled to a second input terminal of exclusive NOR gate 18. The output terminal of NAND gate 16 is coupled to a first input terminal of exclusive NOR gate 20, and the output terminal of exclusive NOR gate 18 is coupled to a second input terminal of exclusive NOR gate 20. The output terminal of exclusive NOR gate 20 provides the partial product of bits a₇and b₇. When bits X and Y have different logic values, i.e., bit X is low and bit Y is high, or bit X is high and bit Y is low, the logic circuit 15 of FIG. 2 is enabled to perform a two's complement logic multiplication operation.

FIG. 3 shows an implementation of those logic gating circuits which provide E₈, E₉, E₁₀, E₁₁, E₁₂, E₁₃ and E₁₄. The logic circuit 21 of FIG. 3 has a first in terminal coupled to receive bit a₇. A second input terminal is coupled to receive bits, to be multiplied with bit a₇, as follows. The logic circuit 21 providing partial product E₈ is coupled to receive bit b₀. at the second input terminal. The circuit 21 providing partial product E₉ receives bit b₁ at the second input terminal. This pattern continues up to the circuit 21 for providing partial product E₁₄, which receives bit b₆ at input terminal B. A third input terminal is coupled to receive bit X.

The first input terminal is coupled to a first input terminal of first NOR gate 22, and to an input terminal of first inverter 24. The second input terminal is coupled to a first input terminal of second NOR gate 26 and is coupled to an input terminal of second inverter 28. Input terminal X is coupled to a first input terminal of third NOR gate 30, and is coupled to an input terminal of third inverter 32.

The output terminal of third inverter 32 is coupled to a second input terminal of first NOR gate 22, and to a second input terminal of second NOR gate 26. The output terminal of second inverter 28 is coupled to a second input terminal of third NOR gate 30, and the output terminal of first inverter 24 is coupled to a third input terminal of third NOR gate 30. The output terminals of first NOR gate 22, second NOR gate 26, and third NOR gate 30 are coupled to first, second, and third input terminal of fourth NOR gate 34, respectively. The output terminal of NOR gate 34 provides partial products E₈, E₉, E₁₀, E₁₁, E₁₂, E₁₃, and E₁₄. The logic circuit of FIG. 3 is enabled to perform a two's complement logic multiplication operation when bit X is high, i.e., a logic 1.

A multiplier circuit according to the invention further includes first, second and third additional logic gating circuits, each having first and second input terminals and an output terminal.

Such additional circuits supply the combinatorial network with signals having a predetermined logic value, unrelated to the binary factors, for addition to the output signals from the other logic gating circuits.

The input terminals of the additional circuits receive the same signals as are applied to the third and fourth terminals of the logic gating circuits for the partial products with two's complement function.

The predetermined logic values of the control signals correspond to the bits X and Y in the above charts, and therefore, are associated with cases a), b), c) and d) of multiplication type.

The additional logic gating circuits are, as mentioned above, ordinary logic circuits of the OR, AND, and EXOR types. FIG. 4 shows the first additional logic gating circuit as OR gate 36. OR gate 36 is coupled to receive bit X at a first input terminal and bit Y at a second input terminal, and provides additive constant P at an output terminal of OR gate 36. FIG. 5 shows the second additional logic gating circuit as AND gate 38. AND gate 38 is coupled to receive bit X at a first input terminal and bit Y at a second input terminal, and provides additive constant Q at an output terminal. FIG. 6 shows third additional logic gating circuit as exclusive OR gate 40. Exclusive OR gate 40 is coupled to receive bit X at a first input terminal and bit Y at a second input terminal, and provides additive constant S at an output terminal.

The electric signals corresponding to the bits X and Y are generated by circuit means in the system which includes the multiplier circuit based upon a determination of either the natural or two's complement form of the binary operands.

FIG. 7 shows a combinatorial network 42 for combining the partial products supplied the logic gating circuits of FIGS. 1, 2, and 3, and the signals supplied by the additional logic gating circuits of FIGS. 4, 5, and 6. As can be seen, combinatorial network 42 includes 37 full adders FA and 5 half adders HA, and includes 4 cascade-connected stages of adders. The adders included in combinatorial network 42 are well known and will not be discussed in detail.

On applying the rules discussed above to the multiplier developed by Dadda, it will be appreciated that the changes made do not affect the delay in computation time. As regards the silicon area occupied, the increase is a modest one. In fact, both the number of the stages (four stages in cascade) and the total number of the adders (37 FAs plus 5 HAs instead of 35 FAs plus 7 HAs) may be left unchanged if the circuit is designed using a method similar to Dadda's .

It should be noted, however, that for the same partial product matrix and functions and additive constants as specified above, in designing a multiplier circuit according to this invention, the column compression portion can be implemented in any of several different ways.

For example, the integration area efficiency can be improved by a distribution of FAs and HAs which is as equal as possible among the various stages and a reduction in the number of interconnects. An example of such a combinatorial network is shown in FIG. 8. Combinatorial network 43 includes four stages of full adders FA and half adders HA. As can be seen, the lowest number of adders per stage is 9; the highest is 12. This distribution of adders is more equal than that of combinatorial network 42 of FIG. 7, in which the number of adders per stage varies between a low of 6 and a high of 4.

Shown in FIG. 9 is a block diagram for an application of a fast multiplier circuit according to the invention which can operate on either forms of binary numbers.

FIG. 9 shows a dedicated arithmetic macro-cell (VCU) 44 for calculating the scalar product (or internal product) of the two integer vectors, adapted to be integrated to a microcontroller using a technology of the VLSI type. The VCU 44 is a macrocell dedicated to the computation of the inner product of two vectors of integer numbers, and is based on the multiply and accumulate algorithm. The macrocell contains two units, interface unit 46 and arithmetic unit 48. Interface unit 46 is controlled by interface control unit 50, and arithmetic unit 48 is controlled by arithmetic control unit 52.

The interface unit 46 fetches the operands from the microcontroller's memories. It includes VCU peripheral register page 54—a page of registers with the addresses of the operands—and a register update unit 56 for updating the registers after each addressing. The arithmetic unit 48 realizes the inner product according to the relationship: S=A*B, i.e., S=a_(i)*b_(i). Arithmetic unit 48 includes a FIFO memory 58 for storing the operands of each multiplication, an 8*8 multiplier 60 and a 32 bit adder 62 for the products accumulation.

The processing speed is usually a concern in integrated circuit microprocessor or microcontroller applications, and accordingly in one embodiment of the invention it is used in integrated circuits in which the mode of inputting the digital signals that represent the operands and outputting the signals that represent the result is of the parallel type rather than serial type.

In another embodiment it is used in a serial type application and can also be used in a mited mode application. Thus, the possibility of it being used in a serial or mixed mode should not be ruled out.

It will be appreciated that the embodiment described hereinabove in an illustrative and non-limitative sense may the subject of modifications, supplements and substitutions of elements without departing from the protection scope of the following claims. 

We claim:
 1. A circuit for generating partial products from a first number and a second number, the first number and the second number having plural bits, the circuit comprising: a first group of logic circuits configured to generate a partial product, the first group of logic circuits having a first input terminal coupled to receive a most significant bit of the first number and a second input terminal coupled to receive a most significant bit of the second number, said first group of logic circuits having a third input terminal coupled to receive a first control signal and a fourth input terminal coupled to receive a second control signal, said first group of logic circuits is enabled to complement the partial product of the most significant bit of the first number and the second number when the first control signal has one of a first and second logic states and the second control signal has an other of the first and second logic states; a second group of NOR-NOR logic circuits configured to generate at least one partial product, the second group of logic circuits having a first input terminal coupled to receive a bit of the first number other than a most significant bit and a second input terminal coupled to receive a most significant bit of the second number, said second group having a third input terminal coupled to receive the second control signal, said second group of NOR-NOR logic circuits is enabled to complement the partial product of the most significant bit of the first number when the second control signal has a first logic state; and a third group of NOR-NOR logic circuits configured to generate at least one partial product, the third group of logic circuits having a first input terminal coupled to receive a most significant bit of the first number and a second input terminal coupled to receive a bit of the second number other than a most significant bit, said third group having a third input terminal coupled to receive the first control signal, said third group of NOR-NOR logic circuits is enabled to complement the partial product of the most significant bit of the first number when the first control signal has a first logic state.
 2. A multiplier circuit for receiving a first binary number having plural bits in the form of n electric signals each having a logic value and a second binary number having plural bits in the form of m electric signals each having a logic value wherein n and m are integer numbers with any desired values, the multiplier circuit providing a product of the first and second numbers in the form of electric signals each having a logic value, the multiplier circuit comprising: a plurality of logic gating circuits, each logic gating circuit having at least first and second input terminals and an output terminal, the plurality of logic gating circuits configured to generate partial products from the input electric signals, the plurality of logic gating circuits including m groups of NOR-NOR logic gating circuits, one of the m signals related to the second number being applied to the first input terminal of all the logic gating circuits in one group, the signal being a different one for each group, and one of the n signals related to the first number being applied to the second input terminal of each of the logic gating circuits in one group, the signal being a different one for each logic gating circuit in one group, all the logic gating circuits of one of the m groups and at least one logic gating circuit in each one of the other (m−1) groups having at least third and fourth input terminals for which electric command signals are applied, and the electric command signals are selectively applied to one of the first and second terminals of the remaining m groups of NOR-NOR logic circuits, whereby each of said m logic gating circuits can be enabled to complementing a partial product of a most significant bit of either and both of the first and second numbers when either and both of the signals applied to the first and second input terminals is in two's complement form; a combinatorial network coupled to the output terminals of said logic gating circuits for performing addition of the output signals from said plurality of logic gating circuits; and first, second and third additional logic gating circuits each having at least first and second input terminals and an output terminal for supplying the combinatorial network with output signals for addition to the output signals from the other logic gating circuits.
 3. A multiplier circuit according to claim 2 wherein logic gating circuits with only two input terminals are of AND type, and the first, second, and third additional logic gating circuits are of OR, AND and exclusive OR types, respectively, and the predetermined logic values of the electric signals are of a first and a second type.
 4. A multiplier circuit according to claim 2 wherein logic gating circuits having third and fourth terminals can be enabled to carry out a two's complement logic multiplication operation of signals applied to the first and second input terminals.
 5. A multiplier circuit according to claim 4 wherein the logic gating circuit with third and fourth input terminals has the most significant bit signals of the two binary numbers applied to the first and second input terminals thereof is enabled to carry out a two's complement logic multiplication operation when the predetermined logic values of the electric signals applied to the third and fourth input terminals are of a first type and a second type, respectively, and further wherein logic gating circuits having third and fourth input terminals and the most significant bit signal of the first binary number applied to one of the first and second input terminals thereof are enabled to carry out a two's complement logic multiplication operation when an electric signal having a logic value of the first type is applied to their third input terminal and an electric signal of the second type is applied to their fourth input terminal, and further wherein logic gating circuits having third and fourth input terminals and the most significant bit signal of the second binary number applied to one of the first and second input terminals thereof, are enabled to carry out a two's complement logic multiplication operation when an electric signal of the first type is applied to their fourth input terminal.
 6. A monolithically integrated circuit device comprising: at least one multiplier circuit for receiving a first number having a plurality of bits in the form of n electric signals each having a predetermined logic value and a second number having a plurality of bits in the form of m electric signals each having a predetermined logic value wherein n and m are integer numbers with any desired values, the multiplier circuit providing a product of the first and second numbers in the form of electric signals, the multiplier circuit including: a plurality of logic gating circuits, including m groups of NOR-NOR logic gating circuits, each logic gating circuit having at least first and second input terminals and an output terminal, each of said logic gating circuits configured to perform a logic multiplication of input electric signals, one of the m signals related to the second number being applied to the first input terminal of all the m logic gating circuits in one group, the signal being a different one for each group, and one of the n signals related to the first number being applied to the second input terminal of each of the m logic gating circuits in one group, the signal being a different one for each logic gating circuit in one group, all the logic gating circuits of one of the m groups and at least one logic gating circuit in each one of the other (m−1) groups having at least third and fourth input terminals for which electric command signals are applied, whereby each of said m logic gating circuits can be enabled to also carry out a type of multiplication operation of the signals applied to the first and second input terminals that includes complementing the partial product of the most significant bit of either or both of the first and second numbers when either or both of the first and second numbers are in two's complement form; a combinatorial network coupled to the output terminals of said logic gating circuits for performing addition of the output signals from said plurality of logic gating circuits; and first, second and third additional logic gating circuits each having at least first and second input terminals and an output terminal for supplying the combinatorial network with output signals for addition to the output signals from the other logic gating circuits.
 7. A monolithically integrated circuit device according to claim 6 wherein the circuit device comprises a microprocessor.
 8. A monolithically integrated circuit device according to claim 6 wherein the circuit device comprises a microcontroller.
 9. A monolithically integrated circuit device according to claim 6 wherein the circuit device comprises an electrically erasable integrated memory.
 10. A monolithically integrated circuit device according to claim 9 wherein the multiplier circuit performs a computation of scalar multiplication of two integer vectors.
 11. A multiplier circuit for multiplying a first number and a second number, the first number and the second number having plural bits, the multiplier circuit comprising: a plurality of groups of logic circuits for providing partial products, each logic circuit having a first input terminal for receiving a bit of the first number, the bit of the first number applied to a group being a same bit, the same bit of the first number applied to a group being different for each group, each logic circuit having a second input terminal for receiving a bit of the second number, the bit of the second number being different for each second input terminal for the logic circuits in a group, all the logic circuits of one group and at least one logic circuit of each other group having NOR-NOR logic circuits and at least a third input terminal for receiving one of a first and second control signal and being enabled to perform a two's complement multiplication of bits applied to the first and second terminals in response to at least one of the first and second control signals, the two's complement multiplication including complementing the partial product of the most significant bit of either or both of the first number and second number when either or both of the first number and second number are in two's complement form, each logic circuit having an output terminal; a combinatorial network coupled to the output terminals of the logic circuits for adding the partial products; and a plurality of logic gating circuits for providing plural logic control signals to said combinatorial network, the logic gating circuits each having first and second input terminals coupled to receive the first and second control signals, the logic gating circuits each having an output terminal coupled to said combinatorial network.
 12. A multiplier circuit according to claim 11 wherein a first group of NOR-NOR logic circuits that has at least a third input terminal has the first input terminal coupled to receive the most significant bit of the first number and the second input terminal coupled to receive the most significant bit of the second number, the third input being coupled to receive the first control signal, and further including a fourth input terminal being coupled to receive the second control signal.
 13. A multiplier circuit according to claim 12 wherein said first group is enabled to perform a two's complement multiplication operation on the bits applied to the first and second input terminals when the first control signal has one of a first and second logic states and the second control signal has an other of the first and second logic states.
 14. A multiplier circuit according to claim 11 wherein a second group of logic circuits that has at least a third input terminal has the first input terminal coupled to receive a bit of the first number other than a most significant bit and the second input terminal coupled to receive a most significant bit of the second number, the third input terminal being coupled to receive the second control signal.
 15. A multiplier circuit according to claim 14 wherein said second group is enabled to perform a two's complement multiplication operation on the bits applied to the first and second input terminals when the second control signal has a first logic state.
 16. A multiplier circuit according to claim 11 wherein a third group of logic circuits that has at least a third input terminal has the first input terminal coupled to receive a most significant bit of the first number and the second input terminal coupled to receive a bit of the second number other than a most significant bit, the third input terminal being coupled to receive the first control signal.
 17. A multiplier circuit according to claim 16 wherein said third group is enabled to perform a two's complement multiplication operation on the bits applied to the first and second input terminals when the first control signal has a first logic state.
 18. A multiplier circuit according to claim 11 wherein said plurality of logic gating circuits comprises first, second, and third logic gating circuits.
 19. A multiplier circuit according to claim 18 wherein said first logic gating circuit comprises an AND gate.
 20. A multiplier circuit according to claim 18 wherein said second logic gating circuit comprises an OR gate.
 21. A multiplier circuit according to claim 18 wherein said third logic gating circuit comprises an exclusive OR gate.
 22. A method of processing operands in a data processing system comprising: generating partial result bits for combinations of one bit of a first operand with one bit of a second operand; complementing only partial result bits for a most significant bit of the first operand or a most significant bit of the second operand using NOR-NOR logic circuits when the first operand or the second operand represents a two's complement value, respectively; and forming a composite result by combining the partial result bits, including any complemented partial result bits.
 23. A method according to claim 22, further comprising providing mode compensation bits for use in forming a composite result.
 24. A method according to claim 23 wherein the act of providing mode compensation bits comprises providing three mode compensation bits.
 25. A method according to claim 22 wherein the complementing only partial result bits further comprises generating an uncomplemented partial result bit for a combination of the most significant bit of the first operand and the most significant bit of the second operand when the first operand represents a two's complement value and the second operand represents a two's complement value.
 26. A method according to claim 22 wherein the partial result bits represent an AND function of the operand bits.
 27. A method according to claim 22 wherein the composite result represents a multiplicative product of the first and second operands. 